(462d) Pressure-Induced Flow and Resultant Orientation of Polyacrylamide Chains Impacts Peak Width in DNA Sequencing Separatoins in Microchannel Electrophoresis
AIChE Annual Meeting
2010
2010 Annual Meeting
2010 Annual Meeting of the American Electrophoresis Society (AES)
DNA Analysis in Microfluidic and Nanofluidic Devices
Wednesday, November 10, 2010 - 1:15pm to 1:30pm
For years, microchannel electrophoresis has provided high-resolution separations of DNA, which in turn has lead to highly accurate sequencing data. Initially, microchannel electrophoresis was performed on a capillary array electrophoresis (CAE) platform. As the need to increase throughput has risen, much work has been done to transition from the CAE platform to a microchip electrophoresis platform. While microchip electrophoresis offers faster separation times, this technology has yet to offer the consistent long-reads of CAE. Previous work in our lab has shown differences in separation performance between CAE and microchip electrophoresis for the same replaceable polymer network; namely the separation efficiency greatly decreases in microchips. To better understand DNA migration in microchip, we looked at the apparent dispersion coefficient of DNA for a number of different linear polyacrylamides and poly(N,N-dimethylacrylamides) polymer networks to determine the extent of band broadening. In this study, the physical properties of linear polyacrylamide networks were found to influence band broadening in a time-dependent fashion. Ultimately, understanding the relationship between the physical properties of the polymer network and band broadening will result in increased read lengths on the microchip platform.